High flux thin-film nanocomposites with embedded boron nitride nanotubes for nanofiltration

• Published in: Journal of membrane science Vol. 597; p. 117749
• Main Authors: Casanova, Serena, Liu, Tian-Yin, Chew, Yong-Min J., Livingston, Andrew, Mattia, Davide
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.03.2020
• Subjects: artificial membranes; boron nitride; Boron nitride nanotubes; calcium chloride; carbon nanotubes; Chemical vapour deposition; films (materials); fouling; humic acids; Interfacial polymerisation; magnesium sulfate; methylene blue; nanocomposites; Nanofiltration; polyamides; polymerization; water treatment; Interfacial polymerisation; Nanofiltration; Chemical vapour deposition; Boron nitride nanotubes
• ISSN: 0376-7388; 1873-3123
• DOI: 10.1016/j.memsci.2019.117749

A novel thin film nanocomposite (TFN) membrane was obtained by incorporating boron nitride nanotubes (BNNTs) into a polyamide (PA) thin selective layer prepared via interfacial polymerisation. The addition of just 0.02 wt% of BNNTs led to a 4-fold increase in pure water permeance with no loss in rejection for divalent salts, methylene blue or humic acid compared to the pure PA membrane. Loadings higher than 0.02 wt% of BNNTs led to agglomeration with overall loss of performance. For the membranes containing 0.02 wt% BNNTs, the pure water permeance was 4.5 LMH@bar, with >90% rejection of MgSO4 and >80% rejection of CaCl2. Fouling tests with humic acid showed a flux recovery ratio of >95% with ~50% lower flux loss during the fouling cycle compared to the polyamide only membrane. These values represent a significant improvement over both commercial polyamide membranes and TFN membranes incorporating carbon nanotubes. We assert that the very small quantity of BNNTs needed to produce the enhanced performance opens the way to their use in water treatment applications where nanofiltration membranes are subject to severe organic fouling. [Display omitted] •Prepared first boron nitride nanotube – polyamide TFN membranes via IP.•Just 0.02 wt% BNNT increases 4-fold pure water permeance with no loss in rejection.•>90% rejection for divalent salts, dyes, and humic acid with >95% flux recovery.